1 / 31

Petri-Nets and Other Models

Petri-Nets and Other Models. Summary. Petri-Net Models Definitions Modeling protocols using Petri-Nets Modeling Queueing Systems using Petri-Nets Max-Plus Algebra. Marked Petri Net Graph. A Petri net graph is a weighted bipartite graph. P is a finite set of places , P ={ p 1 ,…, p n }

junius
Download Presentation

Petri-Nets and Other Models

An Image/Link below is provided (as is) to download presentation Download Policy: Content on the Website is provided to you AS IS for your information and personal use and may not be sold / licensed / shared on other websites without getting consent from its author. Content is provided to you AS IS for your information and personal use only. Download presentation by click this link. While downloading, if for some reason you are not able to download a presentation, the publisher may have deleted the file from their server. During download, if you can't get a presentation, the file might be deleted by the publisher.

E N D

Presentation Transcript

  1. Petri-Nets and Other Models

  2. Summary • Petri-Net Models • Definitions • Modeling protocols using Petri-Nets • Modeling Queueing Systems using Petri-Nets • Max-Plus Algebra

  3. Marked Petri Net Graph • A Petri net graph is a weighted bipartite graph • P is a finite set of places, P={p1,…,pn} • T is a finite set of transitions,T={t1,…,tm} • A is the set of arcs from places to transitions and from transitions to places • (pi, tj) or (tj, pi) represent the arcs • w is the weight function on arcs • x is the marking vector x =[x1,…,xn] represents the number of tokens in each place.

  4. Petri Net Example Transition 0 Place 0 Place 1 Transition 1 Arc with w=1 Arc Place Token Transition • I(tj)= {pi P : (pi, tj)A} • O(tj)= {pi P : (tj, pi)A} • I(pi)={tj T : (tj, pi)A} • O(pi)={tj T : (pi, tj)A}

  5. Petri Net Marking t1 p1 p2 t2 • A transition tjTis enabled when each input place has at least a number of tokens equal to the weight of the arc, i.e., xi≥w(pi, tj) for all pi I(tj) • When a transition fires it removes a number of tokens (equal to the weight of each input arc) from each input place and deposits a number of tokens (equal to the weight of each output arc) to each output place.

  6. Petri Net Dynamics • The state transition function f of a Petri net is defined for transition tj if and only if xi≥w(pi, tj) for all pi I(tj) • If f(x, tj) is defined, then we set x’i=xi + w(tj, pi) - w(pi, tj) for all i=1,…,n • Define • uj=[0,…0,1,0,…0] where all elements are 0 except the j-th one. • Also define the matrix A=[aji] where aji =w(tj, pi) - w(pi, tj) • In vector form x’= x + ujA

  7. Example: Computer Basic Functions a I B c r f f D • Design a Petri-net that imitates the basic behavior of a computer, i.e., being down, idle or busy

  8. Modeling Protocols Using Petri Nets(Stop and Wait Protocol) Transmitter Receiver Frame 0 ACK 0 Frame 1 ACK 1 Frame 0 Timer Timer ACK 0 • The transmitter sends a frame and stops waiting for an acknowledgement from the receiver (ACK) • Once the receiver correctly receives the expected packet, it sends an acknowledgement to let the transmitter send the next frame. • When the transmitter does not receive an ACK within a specified period of time (timer) then it retransmits the packet.

  9. Stop and Wait Protocol: Normal Operation pkt 0 Get Pkt 0 Send Pkt 0 Ack 0 Wait Ptk 1 Wait Ack 0 pkt 1 Get Pkt 1 Send Pkt 1 Wait Ack 1 Ack 1 Wait Pkt 0 Transmitter State Receiver State Channel State

  10. Stop and Wait Protocol: Normal Operation pkt 0 Get Pkt 0 Send Pkt 0 Ack 0 Wait Ptk 1 Wait Ack 0 pkt 1 Get Pkt 1 Send Pkt 1 Wait Ack 1 Ack 1 Wait Pkt 0 Transmitter State Receiver State Channel State

  11. Stop and Wait Protocol: Deadlock pkt 0 Get Pkt 0 Send Pkt 0 loss Ack 0 Wait Ptk 1 Wait Ack 0 loss pkt 1 Get Pkt 1 Send Pkt 1 Wait Ack 1 loss Ack 1 Wait Pkt 0 loss Transmitter State Receiver State Channel State

  12. Stop and Wait Protocol: Deadlock Avoidance Using Timers pkt 0 Get Pkt 0 Send Pkt 0 loss Ack 0 Wait Ptk 1 Wait Ack 0 timer loss pkt 1 Get Pkt 1 Send Pkt 1 timer Wait Ack 1 loss Ack 1 Wait Pkt 0 loss Transmitter State Receiver State Channel State

  13. Stop and Wait Protocol: Loss of Acknowledgements pkt 0 Get Pkt 0 Send Pkt 0 loss Ack 0 Reject 0 Reject 1 Wait Ptk 1 Wait Ack 0 timer loss pkt 1 Get Pkt 1 Send Pkt 1 Wait Ack 1 loss Ack 1 Wait Pkt 0 loss Transmitter State Receiver State Channel State timer

  14. Example: Queueing Model a d t1=a p1 t2=d • What are some possible Petri nets that can model the simple FIFO queue

  15. Example: Queueing Model a d t1=a p1=Q p3=I p2=B t2=s t3=d • A “richer” Petri-net model

  16. Example: Queueing Model with Server Breakdown t1=a p1=Q p3=I p2=B t4=b t2=s t3=d t5=r p4=D • How does the previous model change if server may break down when it serves a customer?

  17. Example: Finite Capacity Queueing Model t1=a p1=Q p3=I p4=K p2=B t2=s t3=d • What is a Petri net model for a finite capacity queue?

  18. Other Petri Net Variations p1 p1 p1 p2 p2 p2 t t t • Inhibitor Arcs: A transition with an inhibitor arc is enabled when • All input places connected to normal arcs (arrows) have a number of tokens at least equal to the weight of the arcs and • All input places connected to inhibitor arcs (circles) have no tokens. DISABLED ENABLED DISABLED

  19. Other Petri Net Variations • Colored Petri Nets • In this case, tokens have various properties associated with them. This can be an attribute or an entire data structure. For example, • Priority • Class • Etc.

  20. Timed Petri Net Graph • In the previous discussion, the Petri net models had no time dimension. In other words, we did not consider the time when a transition occurred. • Timed Petri nets are similar to Petri nets with the addition of a clock structure associated with each timed transition • A timed transitiontj (denoted by a rectangle) once it becomes enabled fires after a delayvjk.

  21. Example: Timed Petri Net t1=a t3=d a d p1=Q p3=I p2=B t2=s • Transitions t1 and t3 fire after a delay given by the model clock structure • Transition t2 fires immediately after it becomes enabled

  22. Petri Net Timing Dynamics • Notation • x is the current state • e is the transition that caused the Petri net into state x • t is the time that the corresponding event occurred • e’ is the nexttransition to fire (firing transition) • t’ is the next time the transition fires • x’ is the next state given by x’= f(x, e’). • N’iis the next score of transition i • y’iis the next clock value of transition i (after e’ occurs)

  23. The Event Timing Dynamics • Step 1: Given x evaluate which transitions are enabled • Step 2: From the clock value yi of all enabled transitions (denoted by Γ(x)) determine the minimum clock value y*= miniΓ(x){yi} • Step 3: Determine the firing transition e’= arg miniΓ(x){yi} • Step 4: Determine the next state x’= f(x, e’) • where f() is the state transition function.

  24. The Event Timing Dynamics • Step 5: Determine t’= t + y* • Step 6: Determine the new clock values • Step 7: Determine the new transition scores

  25. Two Operation (Dioid) Algebras • The operation of timed automata or timed Petri nets can be captured with two simple operations: • Addition • Multiplication • This is also called the max-plus algebra

  26. Commutativity Associativity: Distribution of addition over multiplication Null element Basic Properties of Max-Plus Algebra For example let η= -∞

  27. Example

  28. Queueing Models and Max-Plus Algebra time 0.5 0.5 1 0.5 2 0.5 a 1.5 0.5 0.5 1 1 b t=0 t=0.5 t=1 t=1.5 t=2 t=2.5 t=3 t=3.5 t=4 t=4.5 t=5

  29. Queueing Dynamics • Let ak be the arrival time of the k-th customer and dk its departure time, k=1,…,K, then k=1,2,…, a0=0, d0=0 • In matrix form, let xk=[ak, dk]T then where –L is sufficiently small such that max{ak+vak, dk-L}=ak+vak

  30. Example Determine the sample path of the FIFO queue when va={0.5, 0.5, 1.0, 0.5, 2.0, 0.5, …} vd={1.0, 1.5, 0.5, 0.5, 1.0, …} …

  31. Communication Link t1=a t3=d p1=Q p3=I p2=B p4=C t2=s t4=tx • How would you model a transmission link that can transmit packets at a rate G packets per second and has a propagation delay equal to 100ms?

More Related